CN118181123A - General surgery department instrument processing apparatus - Google Patents

Abstract

The invention relates to the technical field of steel nail polishing, and discloses a general surgical tool processing device which comprises a processing container for holding abrasive materials and spherical steel nails, wherein round rods which are concentrically arranged with the processing container are fixedly arranged in the processing container, a plurality of hollowed-out plates are circumferentially distributed on the side surfaces of the round rods, and the height positions of each hollowed-out plate positioned on the round rods are different; the bottom of the processing container is provided with a vibrating motor which is used for vibrating the processing container at high frequency; through all being different with the high position of every fretwork board, can place round steel nail of batch in the fretwork board with equal volume in batches for can fully rub between abrasive material and the spherical steel nail, can reduce the wearing and tearing between the spherical steel nail in the polishing operation simultaneously.

Description

General surgery department instrument processing apparatus

Technical Field

The invention relates to the technical field of steel nail polishing, in particular to a general surgical tool processing device.

Background

Steel nails are used as medical tools, and the shape and size of the steel nails are selected according to specific operation requirements and implantation sites; spherical steel nails are commonly used for fracture fixation and bone connection, have simple design and are relatively easy to implant and take out; the head of the spherical steel nail is spherical, and the tail of the spherical steel nail is provided with a shorter cylindrical bolt; the surface of the spherical steel nail is usually required to be polished to remove an oxide layer, stains and tiny concave-convex on the surface of the material, ensure the smoothness of the surface of the steel nail, reduce the breeding of bacteria and microorganisms, and be beneficial to meeting the medical and health requirements; for implantable medical devices that are in prolonged contact with the human body, polishing techniques can also eliminate non-uniformities and rough surfaces that affect the biocompatibility of the device, thereby reducing the risk of patient infection and adverse reactions.

In the prior art, when polishing a spherical steel nail, a workpiece and a granular abrasive are mixed in a box body, and friction is formed between the abrasive and the workpiece through vibration, so that the polishing effect is achieved; however, the workpieces and the abrasive materials in the box body are more, the polishing time is generally longer, and the conditions that the workpieces collide with each other in the polishing process exist, so that the quality of the workpieces is affected.

Accordingly, there is a need for a general surgical tool handling device that addresses the above-described issues.

Disclosure of Invention

The invention aims to provide a general surgical tool processing device, which is used for solving the problems that in the prior art, a workpiece and a granular abrasive are mixed in a box body, and friction is formed between the abrasive and the workpiece through vibration, so that the polishing effect is achieved; however, the number of workpieces and abrasive materials in the box body is large, the polishing time is long, and the problems that the workpieces collide with each other in the polishing process, the quality defects of the workpieces are affected and the like exist.

Based on the thought, the invention provides the following technical scheme: the grinding machine comprises a processing container for holding grinding materials and spherical steel nails, wherein round rods which are concentrically arranged with the processing container are fixedly arranged in the processing container, a plurality of hollowed-out plates are circumferentially distributed on the side surfaces of the round rods, and the height positions of each hollowed-out plate positioned on the round rods are different;

The bottom of the processing container is provided with a vibrating motor, and the vibrating motor is used for vibrating the processing container at high frequency.

As a further scheme of the invention: the grinding material and the spherical steel nails in the processing container are poured into the filtering container after the polishing of the spherical steel nails is finished, and the filtering container can swing back and forth to separate the grinding material from the spherical steel nails; a supporting plate is arranged above the filtering container, a plurality of annular partition plates are detachably connected to the lower surface of the supporting plate, and a lifting assembly is arranged on one side, away from the partition plates, of the supporting plate; the supporting plate is driven to move along the axis of the filtering container by the lifting component.

As a further scheme of the invention: the lifting assembly comprises a rotating rod which is detachably connected to the inside of one side, far away from the partition plate, of the supporting plate, a connecting block is arranged on the outer side of the rotating rod, and an electric push rod is detachably connected to the top of the connecting block;

The utility model discloses a steering column, including dwang both ends outside all can dismantle the stopper that is connected with two symmetries and set up, every the both sides of stopper all can be dismantled and be connected with the lug, every the stopper outside is provided with the limiting plate, every the bar inslot has all been seted up to the limiting plate, lug one end sets up in the bar inslot and rather than sliding fit.

As a further scheme of the invention: the filter device comprises a filter container, and is characterized in that an installation frame is arranged on the outer side of the filter container, rotating shafts are rotatably connected to the inner parts of two sides of the installation frame, two ends of each rotating shaft extend to the outer part of the installation frame, one ends, close to each other, of each rotating shaft are fixed with the filter container, the two rotating shafts are connected through a connecting rod, and the connecting rod is arranged on one side far away from the filter container; one end of the rotating shaft is connected with the output end of the servo motor, and the servo motor is arranged on one side of the mounting frame through the fixing plate.

As a further scheme of the invention: clamping grooves are formed in the surfaces of one ends, close to each other, of the two rotating shafts, and clamping blocks matched with the clamping grooves are detachably connected to the surfaces of the two ends of the rotating rod; the rotating rod is in rotating fit with the connecting block; the two rotating shafts are detachably connected with positioning blocks on one sides, close to the clamping grooves, of the rotating shafts, and one ends of the clamping blocks are arranged in the positioning blocks and are in sliding fit with the positioning blocks.

As a further scheme of the invention: the bottom of the partition plate is arranged in a triangular mode.

As a further scheme of the invention: the electric putter, limiting plate all can dismantle the inside lower surface of connecting in the mounting bracket.

As a further scheme of the invention: the height of the upper surface of the positioning block is greater than that of the lower surface of the limiting plate, and the limiting plate is positioned above the rotating shaft.

As a further scheme of the invention: grooves are formed in two sides of the supporting plate, and the size of each groove is larger than the swing diameter of the corresponding positioning block.

Compared with the prior art, the polishing device has the beneficial effects that the height positions of each hollow plate are different, and the round steel nails in batches can be placed in the hollow plates in batches in equal quantity, so that the abrasive materials and the spherical steel nails can be fully rubbed, and meanwhile, the abrasion among the spherical steel nails in the polishing operation can be reduced.

Compared with the prior art, the invention has the beneficial effects that the lifting component drives the baffle to move to the highest point, the position of the baffle is kept motionless, not only can enough space be reserved for the spherical steel nails and the grinding materials, and is convenient for the separation between the spherical steel nails and the grinding materials in the earlier stage, but also the grinding materials and the spherical steel nail mixture piled on the upper layer at the bottom of the filtering container can be scattered by the back and forth swinging of the filtering container, so that the extrusion of the grinding materials and the spherical steel nail mixture on the upper layer to the grinding materials and the spherical steel nails on the lower layer is reduced, and the separation speed of the grinding materials and the spherical steel nails is improved.

Compared with the prior art, the invention has the beneficial effects that along with the reduction of the grinding materials and the screening operation of the spherical steel nail mixture, the lifting component drives the partition boards to move to the lowest point, the hollow cavities are formed between the partition boards and the inner wall of the filter container, the grinding materials and the spherical steel nail mixture are separated into the hollow cavities, the abrasion between the spherical steel nails is reduced, the positions of the partition boards are kept still through the matching arrangement of the convex blocks and the strip-shaped grooves, and the bottom grinding materials positioned in the hollow cavities are screened from the filter meshes at the bottom of the filter container sequentially through the back and forth swing of the filter container.

Compared with the prior art, the invention has the beneficial effects that through the arrangement of the clamping blocks and the clamping grooves, the servo motor can drive the partition plates and the filtering container to swing simultaneously, the partition plates can drive the mixture of the grinding materials and the spherical steel nails which are separated in the cavities to swing together, the upper grinding materials piled in the cavities are rolled to the bottom of the filtering container, and the separation speed of the grinding materials and the spherical steel nails is improved.

Drawings

The invention will be further described with reference to the drawings and examples.

FIG. 1 is a schematic view of the structure of a process vessel of the present invention;

FIG. 2 is a schematic view of a hollow-out plate structure of the present invention;

FIG. 3 is a schematic view of the structure of the support plate of the present invention;

FIG. 4 is a schematic view of the structure of the connecting block of the present invention;

FIG. 5 is an enlarged schematic view of the structure of FIG. 3A according to the present invention;

FIG. 6 is an enlarged schematic view of the structure of FIG. 4B in accordance with the present invention;

FIG. 7 is a schematic view of a latch according to the present invention;

FIG. 8 is a schematic view of the positioning block structure of the present invention;

FIG. 9 is a schematic view of a turning lever structure according to the present invention;

FIG. 10 is a schematic view of the structure of the filtration vessel of the present invention;

fig. 11 is a schematic view of the structure of the separator of the present invention.

In the figure: 1. a processing container; 2. a hollowed-out plate; 3. a vibration motor; 4. a filtration vessel; 5. a support plate; 6. a partition plate; 7. an electric push rod; 8. a connecting block; 9. a rotating lever; 10. a limiting block; 11. a limiting plate; 12. a bar-shaped groove; 13. a clamping block; 14. a rotating shaft; 15. a connecting rod; 16. a positioning block; 17. a servo motor; 20. a groove; 21. a mounting frame; 22. a support frame; 23. and (5) supporting plates.

Detailed Description

As shown in fig. 1 to 2, the general surgical tool treatment device comprises a processing container 1 for containing abrasive materials and spherical steel nails, wherein round rods which are concentrically arranged with the processing container 1 are fixedly arranged in the processing container 1, a plurality of hollowed-out plates 2 are circumferentially distributed on the side surfaces of the round rods, and the height positions of each hollowed-out plate 2 positioned on the round rods are different;

The bottom of the processing container 1 is provided with a vibrating motor 3, and the vibrating motor 3 is used for vibrating the processing container 1 at a high frequency.

During specific operation, the vibration motor 3 is mounted on the support frame 22, a plurality of spring mounting positions are arranged on the upper surface of the support frame 22, springs are mounted on the corresponding spring mounting positions, a support plate 23 is mounted on the top of each spring, the support plate 23 is used for supporting the processing container 1, the support plate 23 and the processing container 1 are fixed through bolts, the device is used for polishing the surface of the spherical steel nail, each hollow plate 2 has a certain depth, so that a plurality of spherical steel nails are placed in each hollow plate 2 in batches in equal quantity, and the bottom of each hollow plate 2 is in a net-shaped design so as to reduce the contact area between the spherical steel nail and the hollow plate 2, so that abrasive materials can fully contact and rub the spherical steel nail; the holes at the bottom of each hollowed plate 2 are smaller than the maximum diameter of the spherical steel nails and larger than the maximum diameter of the abrasive, so that the abrasive can conveniently pass through the holes and simultaneously prevent the spherical steel nails from falling from the hollowed plates 2, and the spherical steel nails arranged in the hollowed plates 2 in batches fall into the processing container 1 to form accumulation, so that the spherical steel nails are mutually impacted to form abrasion in the polishing operation;

After placing spherical steel nails in the hollowed-out plate 2 in batches by equal amount, pouring the abrasive into the processing container 1 again, so that the abrasive completely covers the spherical steel nails, and driving the processing container 1 positioned above the vibrating motor 3 to vibrate at high frequency by starting the vibrating motor 3, so that the abrasive and the spherical steel nails can be fully rubbed, and meanwhile, the abrasion between the spherical steel nails can be reduced in polishing operation.

As shown in fig. 3 to 4, a general surgical tool treatment apparatus further comprises a filtering container 4 for separating the abrasive and the spherical steel nails, wherein the abrasive and the spherical steel nails in the processing container 1 are poured into the filtering container 4 after the spherical steel nails are polished, and the filtering container 4 can swing back and forth to separate the abrasive and the spherical steel nails; the support plate 5 is moved along the axis of the filter container 4 by the lifting assembly.

A supporting plate 5 is arranged above the filtering container 4, a plurality of annular partition plates 6 are detachably connected to the lower surface of the supporting plate 5, and a lifting assembly is arranged on one side, away from the partition plates 6, of the supporting plate 5; the lifting assembly comprises a rotating rod 9, the rotating rod 9 is detachably connected inside one side, far away from the partition plate 6, of the supporting plate 5, a connecting block 8 is arranged on the outer side of the rotating rod 9, and an electric push rod 7 is detachably connected to the top of the connecting block 8.

The electric putter 7, limiting plate 11 all can dismantle the inside lower surface of being connected in mounting bracket 21, and mounting bracket 21 can be used to support electric putter 7 and limiting plate 11.

The outside of the filter container 4 is provided with a mounting frame 21, the inside of two sides of the mounting frame 21 is rotationally connected with rotating shafts 14, two ends of each rotating shaft 14 extend to the outside of the mounting frame 21, one ends of the two rotating shafts 14, which are close to each other, are fixed with the filter container 4, the two rotating shafts 14 are connected through a connecting rod 15, and the connecting rod 15 is arranged on one side far away from the filter container 4; one end of one of the rotation shafts 14 is connected to an output end of the servo motor 17, and the servo motor 17 is mounted on one side of the mounting frame 21 through a fixing plate.

During specific operation, the connecting block 8 is driven to move upwards by starting the electric push rod 7, the connecting block 8 moves upwards to drive the rotating rod 9 positioned in the connecting block 8 to move upwards, the rotating rod 9 moves upwards to drive the supporting plate 5 to move upwards, the supporting plate 5 moves to drive the plurality of partition boards 6 to move upwards to the highest point and then stop moving, the polished spherical steel nails and abrasive materials are poured into the filter container 4, the partition boards 6 move upwards to the highest point, enough space can be reserved for the spherical steel nails and the abrasive materials, separation between the spherical steel nails and the abrasive materials in the front stage is facilitated, one rotating shaft 14 is driven to swing back and forth by starting the servo motor 17, as the two rotating shafts 14 are connected through the connecting rod 15 which is arranged in a U shape, one rotating shaft 14 can drive the other rotating shaft 14 to swing back and forth when swinging back, and one end of the two rotating shafts 14 is fixed with the axle center of the filter container 4, the rotating shafts 14 can drive the filter container 4 to swing back and forth when swinging back and forth to separate the abrasive materials and the spherical steel nails positioned in the filter container 4, and the partition boards 6 arranged above the filter container 4 at the moment can drive the partition boards 6 to stack upper layers and the abrasive materials and the spherical steel nails in the filter container 4 to improve the speed of the separation of the abrasive materials and the spherical steel nails.

Further, as shown in fig. 5 to 8, in order to improve the scattering effect of the upper layer abrasive and the spherical steel nails in the filter container 4, two symmetrically arranged limiting blocks 10 are detachably connected to the outer sides of two ends of the rotating rod 9, two sides of each limiting block 10 are detachably connected with a bump, a limiting plate 11 is arranged on the outer side of each limiting block 10, a bar-shaped groove 12 is formed in each limiting plate 11, one end of each bump is arranged in the bar-shaped groove 12 and is in sliding fit with the bar-shaped groove 12, during specific operation, the rotating rod 9 moves upwards to drive the limiting blocks 10 at two ends of the rotating rod 9 to move upwards together, through the arrangement of the bumps, the limiting blocks 10 can only do vertical reciprocating movement, the rotating rod 9 can only do vertical reciprocating movement along the two limiting plates 11, after the baffle 6 is impacted by the rolling abrasive and the spherical steel nails, the baffle 6 can not swing, the resistance of the abrasive and the spherical steel nails is enabled to be larger when the baffle 6 swings in the filter container 4, the scattering effect of the upper layer abrasive and the spherical steel nails in the filter container 4 is further improved, the separation efficiency with the spherical steel nails is improved, and the grooves 20 are reserved on the two sides of the supporting plates 5, and the grooves 20 are enabled to move to be enough to have enough lengths to be reserved for the grooves 20;

As shown in fig. 8 to 9 and 11, in order to reduce abrasion between spherical steel nails as the abrasive in the filter container 4 is reduced, the filter container 4 is driven to reset by the servo motor 17, then the plurality of baffle plates 6 are driven to move downwards by the electric push rod 7 until the baffle plates 6 stop moving when the rotating rod 9 and the axis of the rotating shaft 14 are positioned on the same horizontal line, at the moment, the plurality of baffle plates 6 are attached to the inner wall of the filter container 4 to form a plurality of cavities, so that the residual abrasive in the filter container 4 and the spherical steel nails mixed with the abrasive are separated into the plurality of cavities, the impact between the abrasive and the spherical steel nails is reduced in the screening process of the spherical steel nails, and in order to facilitate the baffle plates 6 to pass through the abrasive and the spherical steel nails to contact the inner wall of the filter container 4 to form the cavities, the bottoms of the baffle plates 6 are arranged into an inverted triangle shape, so that the spherical steel nails and the spherical abrasive materials can be prevented from being clamped between the baffle plates 6 and the filter container 4;

After the inner walls of the filter container 4 are attached to each other, the servo motor 17 is started to drive the filter container 4 to swing back and forth, the positions of the plurality of partition plates 6 are kept motionless through the matching of the protruding blocks and the strip grooves 12, and the bottom abrasive materials in the cavities are screened from the filter meshes at the bottom of the filter container 4 in sequence through the back and forth swing of the filter container 4.

Further, as shown in fig. 10, in order to increase the separation speed of the abrasive in the cavity, clamping grooves are formed on one end surfaces of the two rotating shafts 14, which are close to each other, and clamping blocks 13 matched with the clamping grooves are detachably connected to the two end surfaces of the rotating rod 9; the rotating rod 9 is in rotating fit with the connecting block 8; one side, close to the clamping groove, of each rotating shaft 14 is detachably connected with a positioning block 16, and one end of each clamping block 13 is arranged in each positioning block 16 and is in sliding fit with each positioning block 16; the upper surface of the positioning block 16 is higher than the lower surface of the limiting plate 11, and the limiting plate 11 is positioned above the rotating shaft 14.

During specific operation, electric putter 7 drive dwang 9 moves down, thereby drive stopper 10 and follow dwang 9 and move to the bottom of limiting plate 11, the fixture block 13 that is located dwang 9 both ends at this moment just in time moves to locating piece 16 in, make fixture block 13 can be located locating piece 16 internal vertical slip, thereby guarantee dwang 9 and remain vertical downward movement throughout, the vertical downward movement of dwang 9 can drive backup pad 5 vertical movement, backup pad 5 vertical movement drives a plurality of baffle 6 and moves down, until fixture block 13 moves to the draw-in groove, the axis of dwang 9 and axis of rotation shaft 14 is located same horizontal line this moment, and through the setting of fixture block 13 and draw-in groove, make dwang 9 and axis of rotation shaft 14 block, drive axis of rotation 14 back and forth oscillation through starting servo motor 17, because the size setting of recess 20 is greater than the swing diameter of locating piece 16, consequently, axis of rotation 14 pendulum can drive dwang 9 swing, the dwang 9 swing, backup pad 5 swing can drive a plurality of baffle 6 and swing jointly, that is just can drive baffle 6 and filter container 4 swing simultaneously through servo motor 17, a plurality of baffle 6 swing to be located spherical and roll the grinding material with the ball-shaped grinding material is stacked in the cavity of a plurality of cavities, the ball-shaped grinding material is stacked on the bottom of the grinding material, the grinding material is stacked in the cavity is high speed with the ball-shaped grinding material is piled up with the grinding material in the grinding material.

In actual operation, when the partition plate 6 passes through the abrasive and the spherical steel nails to be attached to the inner wall of the filter container 4, the filter container 4 and the partition plate 6 can be driven to swing slightly simultaneously by the regulating and controlling servo motor 17, so that the spherical steel nails and the abrasive are prevented from being clamped between the partition plate 6 and the filter container 4.

The foregoing has shown and described the basic principles and main features of the present invention and the advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present invention, and various changes and modifications may be made without departing from the spirit and scope of the invention, which is defined in the appended claims. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (9)

1. A general surgical tool handling device, characterized by: the grinding machine comprises a processing container (1) for containing grinding materials and spherical steel nails, wherein round rods which are concentrically arranged with the processing container (1) are fixedly arranged in the processing container (1), a plurality of hollowed-out plates (2) are circumferentially distributed on the side surfaces of the round rods, and the height positions of the hollowed-out plates (2) on the round rods are different;

The bottom of the processing container (1) is provided with a vibrating motor (3), and the vibrating motor (3) is used for vibrating the processing container (1) at high frequency.

2. A general surgical tool treatment device according to claim 1, wherein: the grinding machine also comprises a filtering container (4) for separating the grinding materials and the spherical steel nails, wherein the grinding materials and the spherical steel nails in the processing container (1) are poured into the filtering container (4) after the spherical steel nails are polished, and the filtering container (4) can swing back and forth to separate the grinding materials and the spherical steel nails;

a supporting plate (5) is arranged above the filtering container (4), a plurality of annular partition plates (6) are detachably connected to the lower surface of the supporting plate (5), and a lifting assembly is arranged on one side, away from the partition plates (6), of the supporting plate (5);

the supporting plate (5) is driven to move along the axis of the filtering container (4) by the lifting component.

3. A general surgical tool treatment device according to claim 2, wherein: the lifting assembly comprises a rotating rod (9), the rotating rod (9) is detachably connected inside one side, far away from the partition plate (6), of the supporting plate (5), a connecting block (8) is arranged on the outer side of the rotating rod (9), and an electric push rod (7) is detachably connected to the top of the connecting block (8);

The utility model discloses a rotary rod, including pivoted lever (9), pivoted lever (9) both ends outside all can be dismantled and be connected with stopper (10) that two symmetries set up, every both sides of stopper (10) all can be dismantled and be connected with the lug, every stopper (10) outside is provided with limiting plate (11), every bar groove (12) have all been seted up in limiting plate (11), lug one end sets up in bar groove (12) and rather than sliding fit.

4. A general surgical tool treatment device according to claim 3, wherein: the filter is characterized in that a mounting frame (21) is arranged on the outer side of the filter container (4), rotating shafts (14) are rotatably connected to the inner parts of two sides of the mounting frame (21), two ends of each rotating shaft (14) extend to the outer part of the mounting frame (21), one ends, close to each other, of the two rotating shafts (14) are fixed with the filter container (4), the two rotating shafts (14) are connected through a connecting rod (15), and the connecting rod (15) is arranged on one side far away from the filter container (4);

One end of one rotating shaft (14) is connected with the output end of a servo motor (17), and the servo motor (17) is arranged on one side of the mounting frame (21) through a fixing plate.

5. A general surgical tool treatment device according to claim 4, wherein: clamping grooves are formed in the surfaces of one ends, close to each other, of the two rotating shafts (14), and clamping blocks (13) matched with the clamping grooves are detachably connected to the surfaces of the two ends of the rotating rod (9);

the rotating rod (9) is in rotating fit with the connecting block (8);

the two rotating shafts (14) are detachably connected with a positioning block (16) on one side close to the clamping groove, and one end of the clamping block (13) is arranged in the positioning block (16) and is in sliding fit with the positioning block.

6. A general surgical tool treatment device according to claim 2, wherein: the bottom of the partition board (6) is arranged in a triangle shape.

7. A general surgical tool treatment device according to claim 4, wherein: the electric push rod (7) and the limiting plate (11) are detachably connected to the inner lower surface of the mounting frame (21).

8. A general surgical tool treatment device according to claim 5, wherein: the height of the upper surface of the positioning block (16) is larger than that of the lower surface of the limiting plate (11), and the limiting plate (11) is positioned above the rotating shaft (14).

9. A general surgical tool treatment device according to claim 5, wherein: grooves (20) are formed in two sides of the supporting plate (5), and the size of each groove (20) is larger than the swing diameter of the corresponding positioning block (16).